Physical contributions to the heat capacity of nickel

Heat capacity data for solid nickel have been re-evaluated and analyzed into physical contributions, 0–1726 K. Two new sets of measurements of C p (Ni), 333–1500 K, have been combined with literature data to produce an evaluated data set with uncertainty ⩽ ± 2%. These smoothed data have been analyze...

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Veröffentlicht in:	The Journal of physics and chemistry of solids 1981, Vol.42 (9), p.861-871
Hauptverfasser:	Meschter, Peter J., Wright, James W., Brooks, Charlie R., Kollie, Thomas G.
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container_end_page	871
container_issue	9
container_start_page	861
container_title	The Journal of physics and chemistry of solids
container_volume	42
creator	Meschter, Peter J. Wright, James W. Brooks, Charlie R. Kollie, Thomas G.
description	Heat capacity data for solid nickel have been re-evaluated and analyzed into physical contributions, 0–1726 K. Two new sets of measurements of C p (Ni), 333–1500 K, have been combined with literature data to produce an evaluated data set with uncertainty ⩽ ± 2%. These smoothed data have been analyzed into vibrational harmonic, electronic, magnetic and dilatational contributions with the aid of auxiliary measurements of expansion coefficient, compressibility, vibrational and electronic densities of states, elastic constants, and magnetic exchange integral and susceptibility obtained from the literature. The vibrational harmonic term is interpreted in terms of a θ D -vs- T curve in accord with predictions of the density-of-states distribution. The electronic contribution is smaller than predicted by free-electron theory due to a large electron-phonon effect. The electronic term for paramagnetic nickel is in good agreement with that predicted from band calculations. The magnetic contribution yields a magnetic entropy in accord with theoretical predictions, and a magnetic internal energy and critical-point behavior in agreement with the isotropic Heisenberg model. The experimental heat capacity can be accounted for without reference to vibrational anharmonic and vacancy contributions, in accord with recent calculations.
doi_str_mv	10.1016/0022-3697(81)90174-8
format	Article
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Two new sets of measurements of C p (Ni), 333–1500 K, have been combined with literature data to produce an evaluated data set with uncertainty ⩽ ± 2%. These smoothed data have been analyzed into vibrational harmonic, electronic, magnetic and dilatational contributions with the aid of auxiliary measurements of expansion coefficient, compressibility, vibrational and electronic densities of states, elastic constants, and magnetic exchange integral and susceptibility obtained from the literature. The vibrational harmonic term is interpreted in terms of a θ D -vs- T curve in accord with predictions of the density-of-states distribution. The electronic contribution is smaller than predicted by free-electron theory due to a large electron-phonon effect. The electronic term for paramagnetic nickel is in good agreement with that predicted from band calculations. 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Two new sets of measurements of C p (Ni), 333–1500 K, have been combined with literature data to produce an evaluated data set with uncertainty ⩽ ± 2%. These smoothed data have been analyzed into vibrational harmonic, electronic, magnetic and dilatational contributions with the aid of auxiliary measurements of expansion coefficient, compressibility, vibrational and electronic densities of states, elastic constants, and magnetic exchange integral and susceptibility obtained from the literature. The vibrational harmonic term is interpreted in terms of a θ D -vs- T curve in accord with predictions of the density-of-states distribution. The electronic contribution is smaller than predicted by free-electron theory due to a large electron-phonon effect. The electronic term for paramagnetic nickel is in good agreement with that predicted from band calculations. 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Two new sets of measurements of C p (Ni), 333–1500 K, have been combined with literature data to produce an evaluated data set with uncertainty ⩽ ± 2%. These smoothed data have been analyzed into vibrational harmonic, electronic, magnetic and dilatational contributions with the aid of auxiliary measurements of expansion coefficient, compressibility, vibrational and electronic densities of states, elastic constants, and magnetic exchange integral and susceptibility obtained from the literature. The vibrational harmonic term is interpreted in terms of a θ D -vs- T curve in accord with predictions of the density-of-states distribution. The electronic contribution is smaller than predicted by free-electron theory due to a large electron-phonon effect. The electronic term for paramagnetic nickel is in good agreement with that predicted from band calculations. The magnetic contribution yields a magnetic entropy in accord with theoretical predictions, and a magnetic internal energy and critical-point behavior in agreement with the isotropic Heisenberg model. The experimental heat capacity can be accounted for without reference to vibrational anharmonic and vacancy contributions, in accord with recent calculations.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/0022-3697(81)90174-8</doi><tpages>11</tpages></addata></record>
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title	Physical contributions to the heat capacity of nickel
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